The present invention relates to a data transmission system, a terminal device, a program, and a method.
Conventionally, a teleconference system has been provided as an example of a system for sharing videos and audio among a plurality of bases connected via a communication network. However, in the conventional system, there is a problem in that data output is often delayed, due to deterioration of the communication state of the communication network. When the data output is often delayed, the sound and image are intermitted, and the participants of the conference cannot properly obtain necessary information.
In this regard, Japanese Patent No. 5000141 (Patent Literature 1) discloses a method of preventing audio from being intermitted, by notifying a transmission terminal that a packet delay occurs in a reception terminal, and reducing the amount of data in the transmission packet excluding audio data in the transmission terminal.
However, the data output is delayed not only due to the transmission delay of the communication network, but in many cases, due to the internal processing delay (processing time period from when data is received to when an output signal is generated) at the data receiving side. Thus, the output delay may not be prevented by just focusing on the communication state of the communication network as in Patent Literature 1.
The present invention has been made in view of the problem in the conventional technology as described above, and an object of the present invention is to provide a novel data transmission system capable of maintaining a stable output of required information.
The present inventors have diligently studied the configuration of the data transmission system capable of maintaining a stable output of required information regardless of the cause of degradation of output quality, found the following configuration, and reached this invention.
According to the present invention, there is provided a data transmission system including a plurality of terminal devices that are connected to a communication network and that transmit or receive content data among the terminal devices. At least one of the terminal devices that receives the content data includes a code amount change requesting unit that, based on an output time interval of an output signal corresponding to predetermined content data, transmits a code amount reduction request to request reduction of a code amount of the predetermined content data while designating a transmission source of the content data as a destination; and a code amount changing unit that, in response to a code amount reduction request transmitted from another terminal device, reduces a code amount of corresponding content data.
According to the present invention, it is possible to provide a novel data transmission system capable of maintaining a stable output of required information.
Hereinafter, the present invention will be described with reference to an embodiment. It is to be understood that the present invention is not limited to the following embodiment. In the drawings referred to in the following descriptions, the same reference numerals denote the same components, and the descriptions thereof are suitably omitted.
In the following, a data transmission system of the present invention will be described based on the preferred application of a “teleconference system”.
Each of the terminal devices 10 is an information processing device that acquires video and audio of the base being installed, and transmits the video and audio to the terminal devices 10 in the other bases. The terminal device 10 also receives video and audio from the terminal devices 10 installed in the other bases, and outputs the video and audio. The relay device 30 is an information processing device that is interposed between the terminal devices 10, and that relays content data. The transmission management device 50 is an information processing device that executes processes (such as login authentication of the terminal device and monitoring communication state of the communication network) required for operating the system and that centrally manages various types of management information.
Each of the terminal devices 10 can transmit a plurality of pieces of content data at the same time. The terminal device 10 also transmits data using the specific session Sd being established separately. For example, the content data may be image data (moving image and still image) and audio data. The content data may also include text data.
The system configuration of the teleconference system 1 of the present embodiment has been briefly described above. Next, the devices that configure the teleconference system 1 will be described.
First, the configuration of the terminal device 10 of the present embodiment will be described.
An operation panel 1150 is formed at the side of the right side wall surface 1130 of the casing 1100. The operation panel 1150 includes a plurality of operation buttons (108a to 108e), which will be described below, a power source switch 109, which will be described below, and an alarm lamp 119. The operation panel 1150 also includes a sound output surface 1151 formed of a plurality of sound output holes, through which the output sound from a built-in speaker 115, which will be described below, is passed. An accommodating unit 1160 in a concave shape to accommodate the arm 1200 and the camera housing 1300 is formed at the side of a left side wall surface 1140 of the casing 1100. A plurality of connection ports (1132a to 1132c) each used to electrically connect a cable with an external device connection interface (I/F) 119, which will be described below, are provided on the right side wall surface 1130 of the casing 1100. A connection port (not illustrated) used to connect a cable 120c for a display 120 with the external device connection I/F 119, which will be described below, is provided on the left side wall surface 1140 of the casing 1100.
The arm 1200 is mounted on the casing 1100 via a torque hinge 1210, and the arm 1200 is rotatable in the vertical direction relative to the casing 1100, within a range of a tilt angle θ1 of 135 degrees.
A built-in camera (will be described below) is installed in the camera housing 1300, and the built-in camera captures images of the conference. The camera housing 1300 is mounted on the arm 1200 via a torque hinge 1310, and the camera housing 1300 is rotatable in the vertical and horizontal directions relative to the arm 1200, within a range of a pan angle θ2 of ±180 degrees as well as within a range of a tilt angle θ3 of ±45 degrees, when the state illustrated in
The external view of the terminal device 10 of the present embodiment has been described above. Next, a hardware configuration of the terminal device 10 will be described.
The terminal device 10 also includes a built-in camera 112 including a lens optical system and a solid-state image sensor (such as a complementary metal oxide semiconductor (CMOS) and a charge-coupled device (CCD)) as an image input device for capturing images of the conference and acquiring image data. An image sensor I/F 113 controls driving of the camera 112.
The external display 120 is connected to the terminal device 10 as an image output device. The display 120 displays images of the conference of the other bases, an operation input screen, and the like, based on image signals (such as video graphics array (VGA) signals, high-definition multimedia interface (HDMI) (registered trademark) signals, and digital video interface (DVI) signals) output from a display I/F 118. The display may also be built in.
The terminal device 10 also includes a built-in microphone 114 as an audio input device, and an audio input I/F 116 controls the input of audio signals from the microphone 114. The terminal device 10 further includes the built-in speaker 115 as an audio output device, and the speaker 115 outputs the sound of the conference of the other bases, based on the audio signals output from an audio output I/F 117.
The external device connection I/F 119 for connecting various external devices can connect an external device such as an external camera, an external microphone, and an external speaker via a universal serial bus (USB) cable and the like. In the present embodiment, it may be configured so that the external camera is driven before the built-in camera 112, when the external camera is connected, and the external microphone and the external speaker are driven before the built-in microphone 114 and the built-in speaker 115, when the external microphone and the external speaker are connected. It may also be configured so that the camera, the speaker, and the microphone are only mounted externally.
The hardware configuration of the terminal device 10 of the present embodiment has been described above. Next, hardware configurations of the relay device 30 and the transmission management device 50 according to the present embodiment will be described. The relay device 30 and the transmission management device 50 are both versatile information processing devices referred to as a Web server. Thus, in the following, the hardware configurations of the relay device 30 and the transmission management device 50 will be collectively described.
The hardware configurations of the terminal device 10, the relay device 30, and the transmission management device 50 of the present embodiment have been described above. Next, functional blocks of the transmission management device 50 will be described.
The transmission and reception unit 51 transmits and receives various types of data with the terminal device 10 and the relay device 30 via the network 80. The terminal authentication unit 52 searches a terminal authentication management table 500 (see
To manage the operation state of a request source terminal that has requested a login, the terminal management unit 53 stores and manages the terminal ID of the request source terminal, the operation state of the request source terminal, the reception date and time when the login request information is received by the transmission management device 50, and the IP address of the request source terminal in a terminal management table 502 (see
The extraction unit 54 searches a destination list management table 504 illustrated in
The extraction unit 54 also searches the destination list management table 504 using the terminal ID of the request source terminal that has requested a login, as a key, and extracts the terminal ID of the other request source terminal having registered the terminal ID of the request source terminal described above as a candidate destination terminal. The extraction unit 54 also searches the terminal management table 502 using the terminal ID of the candidate destination terminal extracted by the extraction unit 54, as a key, and reads out the operation state of the terminal for each terminal ID extracted by the extraction unit 54. Thus, the extraction unit 54 can acquire the operation state of the candidate destination terminal communicable with the request source terminal that has requested a login. The extraction unit 54 also searches the terminal management table 502 using the terminal ID extracted by the extraction unit 54 as a search key, and extracts the operation state of the request source terminal that has requested a login.
The terminal state confirmation unit 56 confirms the corresponding operation state, by searching the terminal management table 502 using the terminal ID or the destination name as a search key.
The destination list management unit 57 adds or deletes the terminal ID of the destination terminal, for each terminal ID of the request source terminals in the destination list management table 504.
The storage/reading processing unit 59 stores various types of data in the storage device 58, and reads out various types of data stored in the storage device 58.
The functional blocks of the transmission management device 50 have been described above. Next, a process executed when the terminal device 10 logs into the teleconference system 1 and participates in the conference will now be described based on the sequence diagram illustrated in
The user first turns ON the power source switch 109 (see
The terminal authentication unit 52 of the transmission management device 50 searches the terminal authentication management table 500 (see
Upon receiving the authentication result (authentication successful), the terminal device 10 issues a destination list request to the transmission management device 50 (step S6). Consequently, the extraction unit 54 of the transmission management device 50 searches the destination list management table 504 (see
Next, the storage/reading processing unit 59 of the transmission management device 50 reads out data in a destination list frame from the storage device 58 (step S8). The storage/reading processing unit 59 then transmits “destination list information (destination list frame, terminal ID, and destination name) including the destination list frame as well as the terminal ID and the destination name extracted by the extraction unit 54, to the terminal device 10 of the destination list request source (step S9). Consequently, the terminal device 10 of the request source stores the received destination list information in a management information storage unit (step S10).
Furthermore, the extraction unit 54 of the transmission management device 50 searches the terminal management table 502 (see
Next, the transmission and reception unit 51 of the transmission management device 50 transmits “terminal operation state information” including the terminal ID used as a search key at S7 described above, and the operation state of the corresponding destination terminal, to the terminal device 10 of the request source (step S12).
Consequently, the terminal device 10 of the request source stores the received “terminal operation state information” in the management information storage unit (step S13). In this manner, the terminal device 10 of the request source can acquire the operation state of the communicable candidate destination terminal, at the current point.
Next, the terminal device 10 of the request source creates and displays the destination list that has reflected the state of the terminal device 10 as the destination candidate, based on the destination list information and the operation state information of the terminal, stored in the management information storage unit.
The process executed when the terminal device 10 logs into the teleconference system 1 has been described above. In the present embodiment, in response to the user selecting a desired terminal device 10 from the destination list (see
The process executed when the terminal device 10 logs into the teleconference system 1 and participates in the conference has been described above. Next, functional blocks of the terminal device 10 and the relay device 30 of the present embodiment will be described.
The code amount change requesting unit 12 is a functional unit to transmit a request for reducing the code amount of predetermined content data (hereinafter, referred to as a code amount reduction request) selected by the user, to the transmission source of the content data, in response to detecting the output delay of the content data. The code amount changing unit 13 is a functional unit to execute a process of reducing the code amount of the transmission data, in response to the code amount reduction request transmitted from the other terminal device 10.
The last output time updating unit 14 is a functional unit to update the last output time (will be described below) of the predetermined content data selected by the user. The transmission and reception unit 15 is a functional unit to transmit and receive various types of data with the other terminal device 10 via the relay device 30.
The relay device 30 of the present embodiment includes a relay control unit 32 and a reduction request history management unit 34.
The relay control unit 32 is a functional unit to transfer the various types of data received from the terminal device 10 to the designated destination. The reduction request history management unit 34 is a functional unit to manage the history of the code amount reduction request received from the terminal device 10.
The functional blocks of the terminal device 10 and the relay device 30 have been briefly described above. Next, the contents of a specific process executed by the functional units illustrated in
The user participates in a conference by selecting a desired destination from the destination list (see
When the user selects the content data the user wishes to transmit via the input screen, the UI control unit (not illustrated) transmits a registration request of the selected content data to the relay device 30 (S1).
Consequently, the relay device 30 assigns a data ID that is unique in the conference in which the terminal device 10 is currently participating, to each content data the registration of which is requested by the terminal device 10a. The relay device 30 also generates content data registration information that is a list of data names and data IDs of the content data registered by all the terminal devices 10 (including the terminal device 10a) that are participating in the conference (S2). The relay device 30 then transmits the content data registration information to the terminal device 10a (S3).
At the same time, the relay device 30 generates a reduction request history management table 600 (updates the content if the reduction request history management table 600 has already been generated) illustrated in (a) of
The code amount change requesting unit 12 of the terminal device 10a generates an output state management table 700 illustrated in (a) of
Subsequently, the UI control unit (not illustrated) of the terminal device 10a generates a selection screen including a list of content data to be received by the terminal device 10a in the conference, based on the content data registration information received from the relay device 30. The UI control unit then displays the selection screen on the display 120 (S6). The user then selects at least one of the content data the user wishes to output without delay, via the input screen. More specifically, the user who regards the comments of the participants in the conference most important may select the audio data of each base, from a plurality of pieces of content data to be received.
In response to receiving an input selected by the user via the UI control unit (not illustrated), the code amount change requesting unit 12 sets the data ID of the selected content data, in the field 702 of the output state management table 700 (S7). (b) of
At the point when the procedure described above has finished, the terminal device 10a transmits the content data thereof to the relay device 30 while designating the other terminal device 10 (10b, 10c, 10d . . . ) as the destination. The terminal device 10a also receives, from the relay device 30, content data of the other terminal device 10 (10b, 10c, 10d . . . ) for which the terminal device 10a itself is designated as the destination. At this time, the data ID is stored in the packet of the content data to be transmitted and received via the relay device 30.
During the conference in progress in this manner, if the time period from when the other terminal device 10 (10b, 10c, 10d . . . ) transmits content data to when the terminal device 10a outputs an output signal corresponding to the data to the output device of the terminal device 10a exceeds the allowable range to become longer, the user of the terminal device 10a senses a delay in image and audio, and the user will have difficulty in recognizing the content correctly.
In regard to this point, in the present embodiment, before the output delay of the content data (image and audio) selected by the user in advance reaches the level sensed by the user, corrective measures are taken to solve the output delay.
In regard to this point, a process executed by the last output time updating unit 14 of the terminal device 10a will be described first. The output delay of content data is caused by the “transmission delay” resulting from the communication state of the communication network and the “internal processing delay” resulting from the processing time period from when data is received to when an output signal is generated. Regardless of the cause, a sign of output delay appears as an increase in the time interval of outputting output signals. In regard to this point, the last output time updating unit 14 stores the system time (hereinafter, referred to as last output time) that is the time when the output signal corresponding to the received content data is last output to the output device, in the field 704 of the output state management table 700. The last output time updating unit 14 updates the value every time a new output signal is output.
More specifically, the last output time updating unit 14 stores the last output time that is the time when the audio output I/F 117 (see
(c) of
The description will continue by returning to
First, upon detecting the output delay of the selected content data, the code amount change requesting unit 12 determines whether the network communication speed measured by a communication speed measurement unit 17 exceeds a predetermined threshold. If the measured value is below the predetermined threshold, the code amount change requesting unit 12 estimates that the cause of the output delay is the “transmission delay”. In addition, the code amount change requesting unit 12 determines whether the CPU usage rate measured by a CPU usage rate measurement unit 18 exceeds a predetermined threshold. If the measured value exceeds the predetermined threshold, the code amount change requesting unit 12 estimates that the cause of the output delay is the “internal processing delay”. The code amount change requesting unit 12 then generates a code amount reduction request including the data ID of the content data the output delay of which is detected, the terminal ID of the terminal device 10a, and the estimated cause (at least one of the “transmission delay” and the “internal processing delay”).
Then, the code amount change requesting unit 12 transmits the generated code amount reduction request to the relay device 30 (S8) while designating the other terminal device 10, which is the transmission source of the content data, as the destination. Consequently, the output state management table 700 is updated (S9). The reduction request history management unit 34 of the relay device 30 then updates the reduction request history management table 600, when the relay control unit 32 has received the code amount reduction request from the terminal device 10a (S10).
In this example, it is assumed that the code amount change requesting unit 12 of the terminal device 10a transmits a code amount reduction request including a data ID “XOS0021A”, a terminal ID “XTK0001” of the terminal device 10a, and the estimated cause (“Network” indicating the transmission delay) to the relay device 30. In this case, in the output state management table 700, as illustrated in (d) of
After the reduction request history management unit 34 of the relay device 30 has updated the reduction request history management table 600, the relay control unit 32 transfers the code amount reduction request received from the terminal device 10a to the other terminal device 10 serving as the transmission source of the content data corresponding to the data ID “XOS0021A” (S11).
The code amount changing unit 13 of the other terminal device 10 that has received the code amount reduction request from the relay control unit 32 of the relay device 30 retrieves the data ID and the estimated cause from the code amount reduction request, and executes a process of reducing the code amount of the content data corresponding to the data ID according to the estimated cause (S12).
More specifically, if the estimated cause is the “transmission delay”, the code amount changing unit 13 executes a process of increasing the compression rate of the target content data (in other words, a process of reducing the bit rate). If the estimated cause is the “internal processing delay”, the code amount changing unit 13 executes a process of reducing the sampling rate for the audio data, and a process of reducing the resolution for the image data. If the estimated cause includes both the “transmission delay” and the “internal processing delay”, the code amount changing unit 13 executes a process of increasing the compression rate as well as reducing the sampling rate for the audio data, and executes a process of increasing the compression rate as well as reducing the resolution for the image data. If the reduction request history management table 600 is updated as illustrated in (b) of
As a result of executing the series of processes (S8 to S12) described above, the terminal device 10a can reliably receive the audio data (data ID “XOS0021A”) of the other terminal device 10 without being intermitted.
Then, the code amount change requesting unit 12 of the terminal device 10a continues to monitor the field 704 of the output state management table 700. As a result, in response to sufficiently solving the output delay of the content data the code amount of which is being requested to be reduced, the code amount change requesting unit 12 generates a notification to withdraw the code amount reduction request corresponding to the content data (hereinafter, referred to as a code amount reduction request withdrawal notification) using the following procedure.
First, upon detecting that the output delay of the content data the code amount of which is being requested to be reduced has been sufficiently solved, the code amount change requesting unit 12 generates a code amount reduction request withdrawal notification including the data ID of the content data and the terminal ID of the terminal device 10a.
The code amount change requesting unit 12 then transmits the generated code amount reduction request withdrawal notification to the relay device 30 while designating the transmission source of the content data as the destination (S13). Consequently, the output state management table 700 is updated (S14). Meanwhile, the reduction request history management unit 34 of the relay device 30 updates the reduction request history management table 600, when the relay control unit 32 has received the code amount reduction request withdrawal notification from the terminal device 10a (S15).
In this example, it is assumed that the code amount change requesting unit 12 of the terminal device 10a transmits the code amount reduction request withdrawal notification including the data ID “XOS0021A” and the terminal ID “XTK0001” of the terminal device 10a, to the relay device 30. In this case, in the output state management table 700, as illustrated in (a) of
In this example, after deleting the request history “XTK0001 (Network)” from the field 606 corresponding to the data ID “XOS0021A” included in the code amount reduction request, the reduction request history management unit 34 of the relay device 30 determines whether all the request history corresponding to the data ID “XOS0021A” have been deleted. As a result, if all the request history corresponding to the data ID “XOS0021A” have been deleted, the reduction request history management unit 34 transfers the code amount reduction request withdrawal notification with respect to the data ID “XOS0021A” received from the terminal device 10a, to the other terminal device 10 having been designated as the destination (S16).
Meanwhile, as illustrated in (b) of
The code amount changing unit 13 of the other terminal device 10 that has received the code amount reduction request withdrawal notification from the relay device 30, retrieves the data ID from the code amount reduction request withdrawal notification, and performs a process of recovering the code amount of the content data corresponding to the data ID, to the standard state before the code amount has been reduced (S17). More specifically, the code amount changing unit 13 recovers the parameter that has been changed to reduce the code amount to the original value, among the compression rate, the sampling rate (audio data), and the resolution (image data) of the target content data.
As a result of executing the series of processes (S13 to S17) described above, the terminal device 10a can receive the audio data (data ID “XOS0021A”) of the other terminal device 10 in original standard quality, as soon as the cause of the output delay has been solved.
The contents of the processes cooperatively executed by the functional units illustrated in
As illustrated in
In the first loop process (step 100), the following steps 101 to 103 are executed on n pieces (n=integer equal to or more than one) of selected data that is content data the user wishes to output without delay. At step 101, it is determined whether the elapsed time period from the last output time of the selected data has exceeded a first threshold T1.
As a result, if the elapsed time period from the last output time has not exceeded the threshold T1 (No at step 101), the process returns to step 101, and it is determined whether the elapsed time period from the last output time of the next selected data has exceeded the first threshold T1.
At step 101, if it is determined that the elapsed time period from the last output time has exceeded the threshold T1 (Yes at step 101), a recovery counter for the selected data corresponding to the determination is cleared to zero (step 102). Then, a code amount reduction request of the selected data is transmitted to the relay device 30 (step 103).
Herein, the threshold T1 described above is defined as the upper limit value of the output time interval of the output signal corresponding to the allowable output delay. If the output time interval exceeds the threshold T1, the user senses a delay in image and audio. The threshold T1 may be a common value for both the audio data and image data, or a specific value may be defined for each type of data.
When the first loop process (step 100) is finished for n-pieces of selected data, the process proceeds to the subsequent second loop process (step 200). In the second loop process (step 200), the following steps 201 to 207 are executed on one or more pieces of content data (hereinafter, referred to as data the reduction of which is being requested) that has been the target of the code amount reduction request in the first loop process (step 100).
At step 201, a threshold T2 is set according to the value of a recovery completion counter (a setting method of the threshold T2 will be described below).
At subsequent step 202, the output state management table 700 is referred to calculate the elapsed time period from the difference between the last output time when a value is last stored in the field 704 corresponding to the data the reduction of which is being requested, and the current time. Then, it is determined whether the elapsed time period is less than the threshold T2.
As a result of the determination at step 202, if it is determined that the elapsed time period is not less than the threshold T2 (No at step 202), the process proceeds to step 207, and the recovery counter for the data the reduction of which is being requested, is cleared to zero.
Meanwhile, if it is determined that the elapsed time period is less than the threshold T2 (Yes at step 202), the process proceeds to step 203, and the recovery counter for the data the reduction of which is being requested is incremented by one. Then, at subsequent step 204, it is determined whether the value of the recovery counter has reached a threshold N.
As a result of the determination at step 204, if it is determined that the value of the recovery counter has not reached the threshold N, the process returns to step 201 again, and sets the second threshold T2 for the next selected data.
If it is determined that the value of the recovery counter has reached the threshold N (Yes at step 204), the code amount reduction request withdrawal notification of the selected data corresponding to the recovery counter is transmitted to the relay device 30 (step 205). Then, the recovery completion counter is incremented by one (step 206).
Upon executing the above second loop process (step 200) on all the data the reduction of which is being requested, the first loop process (step 100) will be started again at the next appropriate timing, and the procedure described above will be repeated thereafter.
The threshold T2 set at the previous step 201 will now be described. As is obvious from the above description, in the present embodiment, the recovery completion counter for the selected data is incremented, every time the code amount reduction request withdrawal notification is transmitted to the relay device 30 for certain selected data. In the preferred embodiment, a suitable threshold function is defined so that a smaller value is output as the value of the recovery completion counter becomes greater. This is to prevent unstable control that is caused by transmitting the code amount reduction request and the code amount reduction request withdrawal notification repeatedly and alternately. Then at step 201, the threshold T2 is dynamically set by using the defined threshold function. In the present embodiment, for example, the threshold function indicated by the following formula (1) may be employed.
T2=T2init−[(T2init−T2min)/N]×Recovery completion counter value (1)
In the above formula (1), T2int indicates the initial value, T2min indicates the time interval during which data corresponding to the output signal is transmitted from the transmission source, and N indicates the limit value of the recovery completion times. In this example, T2int needs to be a value sufficiently smaller than the threshold T1, as well as the value larger than T2min. The value T2int may be a common value for both the audio data and image data, or a specific value may be defined for each type of data (audio or image).
As is obvious from the above description, in the present embodiment, the code amount change requesting unit 12 transmits a code amount reduction request of the selected data to the relay device, immediately after detecting a sign of output delay (S101, S102, and S103). On the other hand, in view of the stable operation, the withdrawal of the code amount reduction request is carried out after the stable output of the selected data has continued for a predetermined time or more (in other words, the code amount reduction request will not be withdrawn until step 203 in the second loop process has been repeated for N times). Thus, it is preferable to define a suitable value according to the object of the stable operation, for the threshold N that is referred to determine at step 204. Also, in the preceding explanation, the threshold T2 has been suitably optimized. However, the threshold T2 may also be a fixed value, and in this case, a suitable value (a value sufficiently smaller than the threshold T1 as well as larger than T2min) according to the object of the stable operation may be obtained experimentally.
In
Also, in the second loop process (step S200) in
In the example of the first loop process, there is a possibility that the detection may fails “when data is output slightly after the threshold” in the case of the checking only performed at regular intervals. Thus, as described above, the process the same as that of the regular check is executed “before” updating the last output time, every time the data to be monitored is output as described above. In this manner, for example, it is possible to operate the control upon detecting a “sign of worsening state” such as it takes four seconds to output data instead of three seconds that is a threshold for determining the blackout. Similarly, in the second loop process, it is possible to make sure that the required process will not be omitted at the timing of the above process performed at regular intervals.
As described above, according to the present invention, it is possible to maintain a stable output of information required by the user, regardless of the cause of the output delay.
The functions of the embodiment described above may be implemented by a device-executable program written in, for example, C, C++, C#, Java (registered trademark). The computer program of the present embodiment can be stored in a device-readable recording medium such as a hard disk device, CD-ROM, magnetic-optical disk (MO), digital versatile disc (DVD), flexible disk, electrically erasable programmable read-only memory (EEPROM), and erasable programmable read-only memory (EPROM) to be distributed, or may be transmitted via a communication network in a possible form by other apparatuses.
Although the present invention has been described above based on the embodiment of the teleconference system, the present invention is not limited to the above embodiment. The present invention may be applied to any data transmission system regardless of use, as long as the system can simultaneously transmit content data between the terminal devices via a communication network. In this case, the terminal device may be a smartphone, a general-purpose personal computer (PC), a tablet terminal, a mobile phone, an electronic blackboard, a projection device such as a projector, and a vehicle navigation terminal mounted on a vehicle, according to the use. It should also be understood that the present invention falls within the scope of the present invention, as long as it exhibits the action and effect of the present invention within the scope of the embodiment that can be easily inferred by those skilled in the art.
Number | Date | Country | Kind |
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2014-042279 | Mar 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/053139 | 2/4/2015 | WO | 00 |